A method for communicating between a user using a viewing device (2000) and the viewing device, includes the following steps: acquiring, at an acquisition interface (1400) integrated into a pair of glasses (1000) of the user, an item of information on utilization of the glasses; and generating and sending to the viewing device (2000), by a microcontroller (1100) integrated into the glasses, a data signal (DATA) depending on the acquired information. The acquired information enables in particular the authentication of the user, so as to send, to the viewing device, data that the latter will use to display a digital content.
Legal claims defining the scope of protection. Each claim is shown in both the original legal language and a plain English translation.
1. A method for communicating between a user using a viewing device and the viewing device, comprising the following steps: acquiring, at an acquisition interface integrated into a pair of 3D glasses for the user viewing a 3D image, an item of information on utilization of the pair of 3D glasses; and using a microcontroller integrated into the pair of 3D glasses, generating a data signal depending on the acquired information, obtaining an encrypted digital content, making an authentication of the user of the 3D glasses based on the acquired information using the acquisition interface integrated into the pair of 3D glasses, obtaining a decryption key stored in a memory of the pair of 3D glasses upon successful authentication of the user on the pair of 3D glasses based on the acquired information, decrypting the encrypted digital content using the decryption key, and sending the data signal to the viewing device, the sent data signal comprising the decrypted digital content, wherein the viewing device comprises a 3D display screen that displays the decrypted digital content, and wherein the viewing device and the pair of 3D glasses are distinct items of equipment, wherein obtaining the encrypted digital content comprises reception, by a communication interface integrated into the pair of 3D glasses, of the encrypted digital content sent by the viewing device, and wherein continuous decryption of the encrypted digital content using the decryption key and continuous sending of the decrypted content to the viewing device are dependent upon repeated continuous detection, by at least one sensor integrated into the pair of 3D glasses, of the wearing of the pair of 3D glasses by the user.
A method for secure communication between a user wearing 3D glasses and a 3D viewing device. The 3D glasses contain a sensor that captures information about how the glasses are being used. A microcontroller inside the glasses uses this information to authenticate the user. If authentication is successful, based on information acquired through the glasses, a decryption key stored within the glasses' memory is obtained. The 3D viewing device sends encrypted 3D content to the glasses. The glasses then decrypt this content using the key. This decrypted content is then sent as a data signal from the glasses to the viewing device, which displays it on its 3D screen. This decryption and sending process is continuous, but only happens if a sensor in the glasses confirms the user is still wearing them.
2. The method of claim 1 , wherein the acquired authentication information is an item of biometric information acquired using at least one sensor integrated into the pair of 3D glasses.
The method of communicating between a user wearing 3D glasses and a 3D viewing device, involves the 3D glasses capturing biometric data from the user via a sensor. A microcontroller inside the glasses uses the acquired biometric data, such as a fingerprint or iris scan, as the authentication information. If authentication is successful, based on information acquired through the glasses, a decryption key stored within the glasses' memory is obtained. The 3D viewing device sends encrypted 3D content to the glasses. The glasses then decrypt this content using the key. This decrypted content is then sent as a data signal from the glasses to the viewing device, which displays it on its 3D screen. This decryption and sending process is continuous, but only happens if a sensor in the glasses confirms the user is still wearing them.
3. The method of claim 1 , wherein the data signal is sent to the viewing device only upon a successful authentication of the user.
The method of communicating between a user wearing 3D glasses and a 3D viewing device ensures secure data transfer. The 3D glasses contain a sensor that captures information about how the glasses are being used. A microcontroller inside the glasses uses this information to authenticate the user. The glasses send decrypted content to the viewing device ONLY if the user authentication is successful, based on the acquired information obtained through the glasses. If authentication is successful, a decryption key stored within the glasses' memory is obtained. The 3D viewing device sends encrypted 3D content to the glasses. The glasses then decrypt this content using the key. This decrypted content is then sent as a data signal from the glasses to the viewing device, which displays it on its 3D screen. This decryption and sending process is continuous, but only happens if a sensor in the glasses confirms the user is still wearing them.
4. A pair of 3D glasses in combination with a separate viewing device, the pair of 3D glasses comprising at an integrated acquisition interface that acquires an item of information on utilization of the pair of 3D glasses, and an integrated microcontroller that i) generates a data signal dependent on the acquired information, ii) obtains an encrypted digital content, iii) makes an authentication of a user of the 3D glasses based on the acquired information using the acquisition interface integrated into the pair of 3D glasses, and, after successful authentication of a user on the pair of 3D glasses based on the acquired information, obtains a decryption key stored in a memory of the pair of 3D glasses, iv) decrypts the encrypted digital content using the decryption key, and v) sends the data signal to the viewing device, the sent data signal comprising the decrypted digital content; and the viewing device comprising a 3D display screen that displays the decrypted digital content, wherein the viewing device and the pair of 3D glasses are distinct items of equipment, wherein obtaining the encrypted digital content comprises reception, by a communication interface integrated into the pair of 3D glasses, of the encrypted digital content sent by the viewing device, and wherein continuous decryption of the encrypted digital content using the decryption key and continuous sending of the decrypted content to the viewing device are dependent upon repeated continuous detection, by at least one sensor integrated into the pair of 3D glasses, of the wearing of the glasses by the user.
A 3D viewing system comprises of a pair of 3D glasses that communicate with a separate 3D viewing device. The 3D glasses include a sensor that captures information about how the glasses are being used. A microcontroller inside the glasses uses this information to authenticate the user. If authentication is successful, based on information acquired through the glasses, a decryption key stored within the glasses' memory is obtained. The 3D viewing device sends encrypted 3D content to the glasses. The glasses then decrypt this content using the key. This decrypted content is then sent as a data signal from the glasses to the viewing device, which displays it on its 3D screen. This decryption and sending process is continuous, but only happens if a sensor in the glasses confirms the user is still wearing them.
5. The pair of 3D glasses in combination with the separate viewing device of claim 4 , wherein the acquired authentication information is an item of biometric information acquired using at least one sensor integrated into the pair of 3D glasses.
The 3D viewing system includes a pair of 3D glasses that communicate with a separate 3D viewing device. The 3D glasses contain a sensor that captures biometric data from the user, such as a fingerprint or iris scan. A microcontroller inside the glasses uses the acquired biometric data as the authentication information. If authentication is successful, based on the acquired information obtained through the glasses, a decryption key stored within the glasses' memory is obtained. The 3D viewing device sends encrypted 3D content to the glasses. The glasses then decrypt this content using the key. This decrypted content is then sent as a data signal from the glasses to the viewing device, which displays it on its 3D screen. This decryption and sending process is continuous, but only happens if a sensor in the glasses confirms the user is still wearing them.
6. The pair of 3D glasses in combination with the separate viewing device of claim 4 , wherein, wherein the data signal is sent to the viewing device only upon a successful authentication of the user.
The 3D viewing system includes a pair of 3D glasses that communicate with a separate 3D viewing device. The 3D glasses include a sensor that captures information about how the glasses are being used. A microcontroller inside the glasses uses this information to authenticate the user. The glasses send decrypted content to the viewing device ONLY if the user authentication is successful, based on the acquired information obtained through the glasses. If authentication is successful, a decryption key stored within the glasses' memory is obtained. The 3D viewing device sends encrypted 3D content to the glasses. The glasses then decrypt this content using the key. This decrypted content is then sent as a data signal from the glasses to the viewing device, which displays it on its 3D screen. This decryption and sending process is continuous, but only happens if a sensor in the glasses confirms the user is still wearing them.
Cooperative Patent Classification codes for this invention. Click any code to explore related patents in that topic.
September 12, 2012
April 18, 2017
Browse 5M+ US patents with plain-English claim translations and AI-generated analysis.